Automatic machine-tool.



R. T. HAZELTON & S. EINSTEIN.

' AUTOMATIC MACHINE TOOL.

APPLICATION FILED JULY 10, 1914.

1,125,686. I Patented Jan.19, 1915.

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AUTOMATIC MACHINE TOOL. APPLIGATTION FILED JULY 10, 1914.

1 1%5 686, Patented Jan.19,1915.

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R. T. HAZELTON & S. EINSTEIN.

AUTOMATIC MACHINE TOOL. APPLICATION FILED JULY 10, 1914,

Patented Jan. 19, 1915.

6 SHEETS-SHEET 3.

Q10 Line/mm R. T. HAZELTON & S. EINSTEIN. AUTOMATIC MACHINE TOOL.

APPLIGATION FILED JULY 10, 1914. 1,125,686

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Patented Jan. 19, 1915.

R. T. HAZELTON &: S. EINSTEIN. AUTOMATIC MACHINE TOOL. 1 .1 1 11101211011 FILED JULY 10, 1914.

1,125,686. r Patented Jan. 19, 1915.

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APPLICATION FILED JULY 10, 1914. 1,125,686, Patented. Jan.19,1915.

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of this joint invention isto effect a reari TED sraans rarnr ra ion ROBERT T. HAZELTON AND SOL EINSTEIN, OF CINCINNATI, OHIO, ASSIGNORS TO THE CINCINNATI MILLING- MACHINE (30., 0F CINCINNATI, OHIO, A CORPORATION OF OHIO.

AUTOMATIC MACHINE-TOOL Specification of Letters Patent.

Patented Jan. is, 19115.

' Application filed July 10, 1914. Serial-No. 850,175. v

S01 Einstein Serial No. 839,718 filed May- 20th, 1914 and Serial No, 843,218, filed June 5th, 1914. i

Among various other objects, this joint 1n-v vention-contemplates a table-propelling organizationwhereby the attendant may by I merely manipulating asingle lever or controller not only cause the table to execute a quick-traverse whenever desired, but whereby he may'also cause it to feed at thepredetermined tooling rate, or may either stop or reverse its direction of travel,

or whereby these operations may be causedv to take place automatically by dog-action under the control of the table.

Anotherobject of the preferred species rangement of conventional machines Whereby the fast running quick-traverse elements, the slower running feed elements and the feed-change-mechanism, together with the cooperating shift devices for reversing the directionof motion as well as for bringing into action either the quicktraverse orthe feed, will all be mounted directly on or otherwise supported by one or more of the mobile frame-units, i. 6., such as are mounted to permit of bodily movement in a vertical direction to vary the distance between the tool-carrying member and the table, as for instance the knee or saddle of a machine of the type illustrated.

Another object Within the contemplation of this invention is to simplify the means instrumental in changing from a quicktraverse to a feed, or vice versa, as well as for changing the direction of movement or for stopping the movement; and to provide a construction enabling the mechanism performing these offices to be compacted or brough to a $llficiently small compass to be located at the front longitudinal edge of the table under the immediate control of the at tendant.

Another object is to coordinate the automatic features providing for intermittentmilling with a table-propelling mechanism embodying a non-translatable but rotatable screw so as to providea convenient handfeed for the table operative through a hand rotation of the feed screw while yet avoiding the necessity of journaling the screw on the table.

Another object is, while maintaining or simplification of a machine-tool by reducing the number oflevers and the complexity of construction heretofore required for its practical operations; and not only to do this but to bring all the levers necessary for the various table movements immediately under the grasp of the attendant when located in the position most advantageously adapted for work inspection.

Another object is to create a control system affording a very adaptable dog-system which can easily be understood by an ordinary attendant and utilized to cause the table automatically to execute various tooling-cycles such as intermittent milling, continuous milling, or the like, to the end that the productivity of the machine will be materially increased.

Another object is to render available a control instrumentality for-a machine-tool whereby the traveling tool or work-supporting element may be controlled automatically Within very close limits and without introducing factors of uncertainty or inaccuracy;

A further and important object of this invention is to create a machine tool in which one of the Working elements may lee-caused to travel either at a quick-traverse rate or at a feeding rate, and which is so constructed that a certain amount of slipping may take place when the movement is abruptly accelerated' from the relatively slow feed rate to the much higher quick-traverse rate, so as to avoid any undue strain of the parts and extending itscapacities, to effect a general whereby an inexpensive and easily replaceable element will be fractured in case undue strains arise during the existence of a positive feeding motion thereby preventing any possible injury to the immediate working elements of the machine.

Another object is to devise a trip arrangeare ment for machine tools in which all of the dogs adjustably secured to the table will be of rigid construction and free from pivots or latch-like characteristics which tend to unreliability and uncertainty in the automatic operation of the machine.

A still further object is to create a trip system providing a first dog series for the advance travel and a second dog series for the retreat travel together with automatic means for bringing the trip means into operative relation with one or the other of said series.

Another object of this joint invention is to construct and arrange the dogs for the trip system in such a manner as to avoid swiveling or latch-like constructions thereby rendering the trip efiect 'more positive and accurate, as well as enabling the dogscontrolling the advance of the table to be positioned independently of the locations of the dogs governing its retreat and without creating any complication or interference due to any swiveling of the dogs; thereby enabling the slot for the upper series of dogs to lie very close to the slot for the lower series of dogs, thus making for compactness.

Another object is to create various improvements in the hand operated mechanism for executing or controlling a shifting of the gears of the feedchange mechanism.

Other objects will be in part obvious from the annexed drawings and in part indicated in connection therewith by the following analysis of this invention.

This invention accordingly consists in the features of construction, combinations of parts and in the unique relations of the members and in the relative proportioning .and disposition thereof; all as more completely outlined herein.

To enable others skilled in the art so fully to comprehend the underlying features thereof that they may embody the sameby the numerous modifications in structure and relation contemplated by this invention, drawings depicting a preferred form have been annexed as a part of this disclosure, and in such drawings, like characters of reference denote corresponding parts throughout all the views, of which Flgure 1 is a side elevation of a millingmachine of a knee-and-column type, exemplifying how any species of milling-mach nes may be reorganized to embody this o1nt' 1nventi on Fig. 2 is a diagrammatic drawing depicting a gear arrangement such as may be used for deriving a series of feeds as well as a quiclntraverse and also for changing the direction of travel of the table; the various gears being brought into I one plane to avoid the confusion incidental to an ordinary drawing. Fig. 3 is a fragmentary view looking down on a table and showing the nesting arrangement of the two dog-actuated parts of the trip-mechanism. Fig. L is a vertical elevation partly in section showing sundry details of the trip or control mechanism, whereby the table may be caused either to feed or make a quicktraverse and whereby its direction of movement may be reversed, or stopped. Fig. 5

is a section through line 55 of Fig. showmg further details of the trip mechanism.

Fig. 6 is a. plan of a detent feature utilized to travel'either to the right or the left. Fig.

8 depicts a comparatively simple or rather elementary dog-arrangement in which the table is intended to be started by hand at a quick-traverse rate to the right and in which the dogs automatically alternate this quicktraverse with a feed duringthis single stroke and ultimately stop the advance of the table while it is feeding; thereby conditioning the table to be started by hand to make a complete return stroke either at a slow or feeding rate concluded by an automatic stop, or at a quick-traverse rate concluded by an automatic reversal at a quick-traverse rate according to the setting made by hand. Fig. 9 shows in elevation the front longitudinal edge of the table with an upper series of dogs producing a travel of the table to the right at alternate fast and slow rates terminating in a reversal of directionwhile maintaining a fast rate; and also showing a lower dog effective near the end of the stroke to the left to change the rate of travel to a feed to enable the dog at the extreme right to stop the travel. Fig. 10 shows another dog arrangement effective to maintain the table in a state of continuousreciprocation while at the same time causing its rate of travel during both the right-hand and the lefthand strokes to alternate between a feed and aquick-traverse. This motion may be termed continuous intermittent milling. Fig. 11 is a side elevation looking to the right of Fig. 10 showing one side ofthe gear-box and its operating levers. Fig. 12 is a plan partly in section through line 1212 of Fig. 11 showing the mechanism for actuating two of the shiftable gear units. Fig. 13 is an elevation of one ofthe elements of the aforesaid mechanism. Fig. 14 is a plan partly in section through line l e-14 of Fig. 11 showing the construction for shifting two other gear units by means of the same hand lever. Fig. 15 is an elevation of one of the elements used in the last mentioned mechanism. Fig. 16 illustrates a front elevation ofaportion of the knee, saddle and which determines the rate at which the table thus feeds; and it is to be distinguished from .variable speed devices which eflect changes not all identified with a tooling-operation, as well as from the speedchange mechanism herein referred to and which determines the speed of rotation of the cutter-spindle.

Before detailing the specific features of construction whereby these functions are attained it will be convenient first to describe certain major elements of a conventional milling machine.- Phese comprise a table Y that supports the work and which is reciprocated to-and-fro to subject the work bolted thereon to the effect of the tool or cutter that is secured to an appropriate tool-supporting member here typified by a spindle X which, in this instance, is con tinuously rotated by power derived. fro

the same source or prime-mover that ac ates the table. In order to enable the machine properly to execute its functions, these actuated elements must be capable of being brought into adjustable relation with one another in two directions. This is accomplished by an interponent frame-unit B that intervenes between the frame-unit A that directly supports the spindle or toolsupporting member and the frame-unit C that directly mounts the table. In the type of machine illustrated, the interponent frame-unit B is commonly termed a knee; the table-supporting frame-unit C is usually termed a saddle, and the spindle mounting frame-unit A is generally 4 ate of termed a column. The chief mechanical characteristic of the interponent frame-unit B is that it provides for a relative vertical adjustment as to the spindle-mounting unit, and a horizontal adjustment as to the tablesupporting unit, 2'. 6., in a direction. transverse to the other.

The spindle mounting frame unit, or column A, has heretofore been that also selected to rest on the floor and thus provide a foundation for the machine, as a whole, and it has alsobeen utilized to support or mount-both the change-gear mechanism that varies the speed of the spindle, as well as the change-gear mechanism that varies the 1-ee d-v of the tableI however;

has resulted in a very considerable inconvenience to the attendant in manipulating the machine. That is to say, the attendant must be stationed at the outer longitudinal side of the reciprocating table in order to scrutinize the action of the machine, but, when so stationed, he is out of reach of the levers that effect all the changes of the rate of feed of the table, so that, in order to make these changes he must shift his position. This invention proposes, among other things, a rearrangement and a reconstruction of the control elements so as to free the so-called column of the machine from the mechanism that governs the rate at which the table shall feed, and so to locate the said mechanism, and so to combine it with other control features that the attendant, when stationed at the outei longitudinal edge of the reciprocating table (the edge remote from the frame-unit that uprises across the plane of the table) and -without shifting his position, will be able,

first, to change the rate at which the table feeds, i. 0., to vary its speed during a cutting-stroke; second, to change the direction of travel ofthe table, either manually or automatically; and third, to stop the movement of the table either manually or auto matically. In carrying out this aspect of this invention, one of the frame-units car'- rying the weight of the table may assume any conventional proportions or configuration, such as are 1nd1cated' on the drawlngs, but

with this distinction, that it is contrived also to support orcarry the weight of what maybe termed a feed-change box, 11. 6., the casing and elements constituting a change-gear mechanism such-that the rate of feed may be varied at will. This box may also include other control features, such as the means for determining the direction of movement of the table.

A more comprehensive grasp of the various aspects ofthis invention may perhaps be obtained'bytracing the course of motion through the machine in connection with a description of the structural features involved.

At convenient point, as for example on a column A, is mounted a prime-mover P. here instanced as a pulley, and both the spindle and the table may be driven by this prime-mover.- Thus, the shaft 79 on which the pulley P is mounted, may (see Fig. 1) carry a. number of gears 6 e and e which are rotatable with the shaft. Each of these gears is rendered selectably available as a transmitting element by meshing it with the appropriate one of the gears E E E (which are mounted as a unit on a sleeve splined to the shaft E) by shifting the gear unit through the hand-lever E*. This causes gear E to transmit motion at the rate determined by thev intermeshing of the above mentioned gears. This motion is in turn communicated to the spindle X, as by means of a gear X operatively connected thereto in an appropriate manner. In the embodiment under description, another transmission system derives motion directly from the prime-mover and includes the beveled gear 1 secured to the shaft 79 and meshing with a beveled gear 2 which is 10- ca d at the upper end of a shaft 8 which depends alongside of the frame-unit A or /o'lumn and enters a box at the side of said frame-unit; Within which it terminates in a bevel 4 that meshes with the bevel 5 secured to the horizontal knuckle 6. The foregoing embodiment constitutes a'very simple structure for so locating the knuckle 6 that the deflection necessary for shaft 7 will be reduced to a minimum. The motion is then received by a knuckle 8 that is keyed to a shaft 9 which, in this embodiment, may be regarded as the initial terminal-member forming a junction from which branches both the quick-traverse transmission as well as the feed-change transmission, as will be explained. The ultimate or last terminal-member for these transmissions is a sleeve 10 loosely mounted on the shaft 9 and adapted to be shifted thereon so as to be connected on the one hand with the quicktraverse transmission, or on the other hand with the feed-change transmission as by means of appropriate clutch teeth at its respective ends. This sleeve 10 may be shifted or positioned by an automatic trip instrumentality, to be subsequently described, and, in splined relation with it, is a beveled gear 11 which is restrained against axial movement and meshes with a bevel 12 here shown as secured to a shaft 13, which in turn carries abeveled gear 14 at its upper end and which meshes both with the bevel R and the bevel L which are journaled in the table support C, here instanced as a saddle. Passing through these bevelgears R and L is a sleeve 15 which is nor- .mally in loose coaxial relation with these bevels, but which is splined to the shaft 16. In this embodiment, this shaft or feedscrew 16 is fixed against translation by means of the collars 17, and it is provided with screw-threads 18 meshing with a nut 19 that is non-rotatably mounted on the table Y so as to translate therewith. By this means, the table will be caused to travel at the rate determined by the rotation of the screw-shaft 16.

A motion-reverser is interposed in the transmission extending from 10 to 19 and it comprises a clutch-member J which is splined to the sleeve 15 and carries clutchteeth at its ends whereby it may be engaged with corresponding teeth on the beveled gears R and L, so that, when the clutch member J is shifted to the one side, the table will be caused to travel to the right and, when it is shifted to the other side, the table will be caused to travel to the left. When this clutcl1member isshifted on the sleeve 15 to an intermediate position, no motion at all will be transmitted, and hence the table will cease to travel. 'The means for automatically operating this motion reverser will shortly be explained.

The quick-traverse transmission, which extends from the initial terminal element 9 to the ultimate terminal member 10, is shown as of a very short and direct nature in this embodiment of this invention. Here, it merely comprises a disk I integral with or keyed, as shown, to the shaft 9. An element I typifying a frictional or yielding part is pressed against the disk I, as by means of a part I which is non-rotatably retained by the cup-like end of a sleeve I which is in turn journaled in the wall of the box mounting the transmission system so as loosely to circumscribe the. end of the shaft 9. By screwingup the follower I any desired pressure may be brought to bear on the two sides of the intervening friction-element I so that the sleeve .1 will be frictionally driven at a rate corresponding to the shaft '9. These parts constitute a quick-traverse transmission having an impositive driving capacity, 6., one embodying a frictiondrive so that. when the quick-traverse transmission is thrown abruptlv into action, a slight slip or yield will' result in the drive to relieve the inertia and save the parts from the otherwise damaging strains of an'unduly abrupt action. The sleeve 10, when shifted to the right as seen by Fig. 2, will become engaged with the sleeve I by means of its'clutch-teeth so that a driving-relation between these two parts will then exist with the result that motion will be imparted to the table at a quick-traverse rate. The motion appropriate for tooling operations is obtained by gearing down or reducing the motion of the shaft 9 through a suitable feed-change mechanism so as to obtain any desired rate of reduced travel corresponding with the tooling to be done.

The feed motion transmission, including the gearing enabling the rate of feed to be varied, will now be described. In this embodiment, this transmission also extends from the initial terminal-member 9 to, the ultimate terminal-member 10, which in this instance is shiftable. Thus, a pinion d is keyed to the shaft 9 and meshes with the gear 03 which is keyed to the shaft 03 so as to drive it. shiftable gear-units d andd The former carries the gears d and d, and the latter carries the gears (Z and d", and the purpose of enabling these gear bearers to be shifted is to utilize one or another of said Splined to this shaft are two four gears for propelling or transmitting parallelism with shaft d is a series of gears D, D D D and D which is so arranged that gear (i may be'brought into mesh with gear D, and so on. In a suitable manner, motion is derived from one of these five gears. Thus, the gear-unit g carries a gear 9 which may be brought into mesh with gear D by a lateral movement of the unit 9, or similarly the gear 9 may be meshed with gear D Inasmuch as the unit 9 is splined to a sleeve 9 the latter will be rotated at a rate dependent upon the character of the foregoingintermeshing; with the effect that gear 9 which is fast to the sleeve 9 will directly drive the gear G and indirectly the gear G at a corresponding rate. The gearCr and the sleeve 9 constitute terminal members, either of which may be brought into propelling relation with a gear 72, which is splined to and therefore drives the shaft k connection is effected on the one hand by the teeth of the gear G and on the other hand by the clutch-teeth at the end of the sleeve 9 Fixed to the end of theshaft 7L1 is a driving disk k which carries a shear pin le -that projects into a corresponding recess in the companion disk It and thereby drives the gear 72, The purpose of this pinarrangement is to centralize all possibility of fracture onthe pin its so as to cause the breakage to occur in an easily replaceable element in case of any undue load. By this construction, a positive drive for all safe loads is insured during all tooling operations thereby enabling definite feeds and effects always to be secured, while yet avoiding any consequential damage to the machine in the event of excessive loads due either to accident or bad judgment on the part of the attendant. By combining this positive feed safety device with the abovedescribed impositive quick-traverse safety means, the attendant becomes able safely to urgethe machine to its utmost output from all standpoints. It should be noted that a primary characteristic of this comboth for the relatively slow, but necessarily powerful feed of the table, as well as for the speedier and less resisted quicktraverse of the table. In accordance with this invention, the safety feed device will be so constructed as to transmit a predetermined stress such that the table will be fed against the resistance of safe tooling operations, and yet so as to yield or fail to transmit should an undue resistance accrue. For example, in this instance, the safety feed device will transmit the power neces- This sary to feed the table-against a resistance of from four to five tons pressure as a maximum. This will suffice for the tooling operations. The cooperating safety means, however, which exercises its office during the quick-traversing of the table is-designed .to yield under materially less stresses so that the table may be propelled against a resistance of only about one-fourth or onefifth of that above-mentioned, say of one ton, since it is necessary for shock-absorbing purposes to use a comparatively free-acting yieldable friction means in handling the momentum or inertia of the parts. The gear k in turn permanently meshes with gear H which in this embodimentconstitutes a terminal member of the feed transmission. That is to say, the gear H has clutch teeth whereby it may be connected with the ultimate terminal-member 10, when it is properly shifted, and thereby cause the motion to be transmitted at the appropriate feeding rate, instead of at the quiclotraverse rate. Inasmuch as the members d and (Z enable four feed-changes to be made, and the member 9 introduces two other "multipliers in serial relation with these changes, and the member it also introduces two more multipliers in serial relation, it will therefore be evident that four times two times two, or sixteen difierent changes of feed are rendered available. The means whereby the above mentioned clutches or their shiftable elements maybe moved both manually and automatically will now be detailed.

Referring to Fig. 4, U denotes a handlever that is adapted to oscillate in two directions, i. 6., about a horizontal axis to determine the speed of travel of the table (up yielding a quick-traverse, and down giving a feed), and about a vertical axis to determine the direction of the travel, or to bring the table to a stop. This mechanism may best be understood by'analyzing the construction in relation to each of the several elemental positions of this hand-lever U. Assuming the table to be stationary, then will the hand-lever U be located in a plane lying at right angles to the path of the table. In other words, the handle of the hand-lever U will be in the intermediate position shown by Figs. .3 and 4, and, when in this position, the clutch-member or 1110- tion-reverser J, will also be in the intermediate or zero position, as illustrated by Fig.

This follows because of the construction and relation of the parts intervening between thehand-lever U and the clutch J,

and will now be described.

and this shaft K is restrained against vertical movement as by means of these two parts. The angular position of this shaft is determined manually by means of a pin U by means of which it is pivotedly connected to the hand-lever U so that any latelement N and the absolute positions in.

space of this element are in turn utilized to control the motion-reverser and the ratecontroller of the table. That is to say, the element N here assumes the form of a plunger which is so mounted in the adjacent portion of the saddle or table-support that it may be shifted in an axial or up-and-down direction as well as turn about this axis. The axial shift is controlled by the lip U of the hand-lever and the rotations or angular positions of the plunger with relation to its axis are determined by the gear-segment K This is done by causing the lip U to coact with the circumferential spline N and one or more of the teeth of the geansegment K similarly co-act with the, axial spline-ways N of the plunger. When the hand-lever U is down, as shown by Fig. 4, the plunger N will be elevated and a pin N secured thereto will then be located in the narrow portion of a slot or opening M of a gear M which is rotatably carried by an adjacent part of the saddle and which meshes with the end of the long arm 0 of a lever O which has its other end forked as indicated by O and provided with shoes entering the circumferential groove in the clutch-element or motion reverser J. The

intermeshing relation between the arm 0 and the gear M is such that, when the pin N is in the narrow portion of the slot and the hand-lever is therefore in the position shown by the drawings, no appreciable lostmotion will exist and the various parts will be retained in the position shown by the spring pressure of the detent devices now to be described.

The detent means for determining and maintaining the angular position of the gear M comprises a spring pressed plunger 30 mounted to reciprocate in the opening 31 in the table-support and prevented from turning therein by means of a pin or stud 32 entering a slot or spline in the pin 30. This pin is normally urged to project farther out of its slot by means of an expansile is adapted to enter a V-shaped notch N in the end of a projection N extending from the cam N. This cam is rigidly pinned to the trip plunger N and, when the latter is in upraised position, this cam N co-acts with the pin 30, as has been described, and

the V-shaped end 35 of the pin holds the parts in the position shown, a. (3., either in midway or neutral stopping position as shown by Fig. 6, or else displaced from this position, either to the right or to the left. By oscillating the hand-lever U, or by ro tating the plunger N by dog-action, the parts may be brought into any one of the three available positions. For example, the V-shaped end of the spring-pressed pin will be caused to shift to one side or the other of the projection N by a part-way positive motion, with the effect that the pressure of the spring will then take on and continue the inaugurated movement and complete it as soon as any positive obstruction (such as a failure of the clutch teeth to intermesh in the first instance) is withdrawn. Preferably, the variousv parts are arranged some-- what as shown, so that when the hand-lever Uis turned clockwise to bring the handle to the left, then will the table travel in a similar direction, a. 6., to the left; or conversely, so that a swing of the handle to the right will cause the table to travel to the right. In other words, a swing of the lever U to the right will move the lever O anti-clockwise and cause the clutch J to intermesh with the gear R, or conversely a swing of the lever U to the left will cause the clutch J to engage the gear L, as shown by Fig. 2. It will be seen that the travel of the table may thus be reversed irrespective of the vertical position of the plunger N, e. 9., regardless of whether the table is feeding or whether it is traveling at a quick-traverse rate. It may also be noted, however, that while thehand-lever may be forcibly held in position to stop the table under quicktraverse conditions, 2'. 6., while elevated, it will remain in that position only when the control mechanism is set to cause the table to feed for the reason that a depression of the plunger N (quick-traverse position) will bring the pin N into a wider portion of the slot M and simultaneously bring the cam N into co-action with the pin 30, and, as this cam N has no provision corresponding with the notch N but in other respects corresponds with the cam N the pin 30 will maintain it in either one of the two positions indicated bvr or Z on Fig. 7 without permitting an intermediate or neutral position corresponding with a stop of the table. In other words, it will only be maintained either in the position of a forward or of a rearward travel of the table. The means whereby an axial movement of the plunger N will determine the rate at which the table travels may now be detailed.

The plunger N is provided with a series of circumferential threads or spline grooves N which mesh with a gear-segment 4O loosely mounted on the end of a shaft 41 and having its hub 42 provided with a radial slot in'which loosely plays a pin'43 which is rigid with the shaft 41. This provides a certain amount of lost motion so that no parts may be broken by the positive unyielding movement imparted by the dogs to the plunger N. This gear-segment 40 is provided with two notches 44 and 45 coacting with a spring-pressed detent or pin 46, so that when the plunger N throws the gear-segment sufiiciently to cause the pin ,6 to override the peak of the middle pro.- jection, then will the throw be completed by an operation of the spring 47 Referring to Fig. 4, 48 indicates a helical feather on the shaft 41 which co-acts with of the part 49 and the clutch-sleeve 10 will be shifted either to one side or the other to connect the quick-traverse transmission in operative relation With the other transmitting elements or toconnect the feed transmission therewith, as the case may be. It may here be stated that the slant or pitch of the feather 49 is in such a direction as to shift the clutch sleeve to the right when the outer end or handle of the handlever U is uplifted.

An understanding of the various characteristics of this mechanism and of its adaptability for various more or less involved automatic operations will best be obtained by an analysis of a few typical examples.

Fig. 8 depicts a comparatively simple arrangement. Assume the table to be stationary with the trip-mechanism positioned immediately to the right of the dog The hand-lever 'U will then coincide with its median vertical plane and will be either.

above or below its horizontal median plane. The attendant, in desiring to start the table to the right, will now shift the hand-lever U to the right of its median vertical plane (if it does not already lie on that side),

' thereby bringing its projecting portion or pin 20 into the path of travel of the upper series of dogs mounted on the table, as.

shown by Fig. 8, 2'. e., the series controlling the rate of travel of the table to the right, as at a feeding rate if the hand-lever U happens to lie below its 'median horizontal plane, or at a quick-traverse to the right if it lies above such plane. Assuming that in order to save time, the attendant has lifted up the lever U, then the table will speed to the right until the contact-surface f of the dog F+ impacts the contact-surface f-fof the pin 20 of the trip-member N which will be in a depressed position. The effect of this impact is to-elevate the trip member N, thereby shifting the clutchmember 10 to the left, as seen by. Fig. 2, so as to connect the feeding-transmission in operative or propelling relation with the table, thereby causing the table to feed to the right. The cutter is now supposed to start performing a tooling-operation on the work and this will continue while the table feeds to the right. Immediately after the cutter leaves the work, the dog H- impacts its contact-surface r] with the contact surface 9-!- of the pin 20, thereby depressn g the trip-memberNand throwing the clutch member 10 to the right to bring the quicktraverse transmission into operation so as to cause the rate of travel of the table quickly to increase and speed it to the right during the non-tooling interval. This may be repeated as frequently as desired by duplicating the above mentioned arrangement of dogs. In order to enable the table to stop automatically, a dog F will be arranged near the end of the stroke of the table so that its contact-surface 7 may impact the contact-surface f+ and elevate the trip-member N. The reason? for this, in this embodiment of this invention, is that the parts are so arranged that the tablepropelling mechanism may automatically be set into and maintained in a stop-position whenever the trip-member N is elevated or in its feeding-position. The table, therefore, is now feeding to the right and the dog Z-l-O will shortly contact the arm K and turn the member K, as well as the hand lever U, clockwise, so as to rotate the tripmeinber N anti-clockwise until the clutch member J of the motion reverser interrupts the transmitting capacity of the propelling mechanism; in which position it is maintained by the entry of the detent pin into notch N of the cam N*. The table is now stopped. It may, however, be started to the left at a slow or feeding rate, by sim ply throwing the hand-lever U to the left and without raising it; in which event, the table will slowly feed to the left throughout its full stroke and will automatically stop as soon as the dog Z-O reverses the position of the arm K and stops the table.

If, however, the attendant should also raise the hand-lever U, in addition to shifting it would, at the end of its left stroke, immediately again make a short quick-traverse to the right until the dog F I became effective to reduce its travel to a feed. A somewhat more elaborate arrangement may now be understood.

Referring to Fig. 9 and, assuming the trip-mechanism to be positioned between the dog ZO and the dog F-|, let the attendant start the table to the right at a quick-traverse rate as before. Contact surface f of the dog F+ will shortly impact the contact-surface f-iof the pin 20 of the trip-member N and the latter will be elevated and the table will feed to the right until the contact-surface g of the dog Q+ impacts the contact surface q-I- of the pin 20 and depresses the trip-member, thereby causing the table to execute a quick-traverse to the right until its rate is reduced to a feed by the action of dog F table will then feed to the right until the dog Q causes its contact-surface g to impact the contact-surface g| of the trip-member N and depress it; whereupon the table will again go to the right at a quick-traverse rate until the dog Z| swings the arm K clockwise with the effect'of reversing the direction of travel of the table without changing its rate. It is noteworthy in this connection that, although dog Z+- is identical in structure and location with the dog Z-i-O shown on Fig. '8, nevertheless .its

effect is entirely different since it reverses without changing the rate, whereas the other merely stops, and the reason for this lies in the fact that its relation to the pre ceding dog. is entirely different in the case of Fig. 9 than in the case of Fig. 8, since in Fig. 9 the preceding dog imparts a quicktraverse to the table, whereas in the case of Fig. 8 it imparts a feed to the table.

Referring again to Fig. 9 and continuing the description thereof, it may be explained that the reason the dog Z[ reverses the travel ofthe table, is because when it acts through the part K to turn the trip-member N, the pin N is depressed and lies in the broader or wider part of the slot DI so that the detent-device, which acts in relation to the cam l will act by spring-pressure to throw the clutch J entirely past its neutral or intermediate position and into interlocking position with the gear L. This connection causes the table to travel at a quick-traverse rate to the left. By placing'a dog F near the end of the stroke of the table, the end dog ZO is enabled automatically to stop the table. That is to say, as a result of the effect of the dog Z+-., the upper pin 20 of the trip-element N has been swung to one side out of action of the upper series of dogs and the lower pin 21 has been swung into position to be impacted by any dog or dogs secured in the lower slot of the table.

Accordingly, when the pin 21 reaches the dog F, the contact surface f thereof will impact the contact-surface fof the pin 21 and raise the trip-member N, thereby causing the table to feed to the left through the distance intervening between this "dog and the dog Z-O, and as soon as this last dog impacts the arm K it will send the pin 21 out of action and will bring the pin 20 into effective position and also stop the travel of the table in very much the same way that dog Z+O in Fig. 8 stopped the table. Had the dog F been removed, the dog at the extreme right would have had a different effect, since it would then have reversed the direction of travel of the table without stopping it. This will be understood by a description of the application of this construction for continuous milling.

Referring now to Fig. 10, and assuming that the trip mechanism is located immediately at the right of the dog Z+ and assuming that the attendant has started the table to the right at any speed, then if that speed be a quick-traverse the dog F+ will permit it to continue as the feed. The table will then feed to the dog Q and then quick-traverse to the right to the dog Z+, whereupon its direction will be reversed and it will travel at the same quick-traverse rate to the left to the first dog F- of the lower series. It will then feed to the left to the dog Q- and then quick-traverse to the dog F and then feed to the dog Q,-} which reverses its direction without changing its rate; and thecycle will be repeated. It is noteworthy that the upper series of dogs is quite independent of the lower series so that the table may act in one direction and may operate in another way in the other direction.

The hand-operating mechanism for enabling the attendant to shift the various "gears of the feed-change mechanism so that the table may be caused to feed at any one of the selectively available rates of feed, which in this instance are sixteen, may now be described. This mechanism embodies certain improvements simplifying its constructlOl'l fllld also enhancingits facility of operation. In this embodiment, two handlevers are utilized, the one controlling the four feed-changes constituting what may be termed the first series of multipliers; and the second lever controls what may be termed the second and also the third series of multipliers. The first lever is indicated by the character D on Figs. 11 and 12 and it comprises an arm or shank 50 that extends through an X-slot ina positioning or guardplate 51 that projects laterally from the side of the gear-box- C which contains the feedchange mechanism as aforesaid. This brings the grip of the lever D adjacent the front longitudinal edge of the reciprocating-tahle wile-e it will at 'alltimes bewithin" the immediate grasp of the attendant. The other end of the leveris flattened to form a gear-segment which"isyreceived by a radius-slot 53 provided by the end-portion B-t'of an elongated sleevefifi'whih extends transi 'ersely to thehand lever D- and is ournaledin the gear-box C so as to permit of rotation, but not of a-n'axial movement. The

other end. of'ithis sleeve 55 provides an-oifset gears 'to'fine s'h with another gear, and so' that when-the hand-lever 1s -1n an intermedii ate position, .the gear imit'zl will also be in anijinter-mediate or non-transmitting "positlOnQ In the arrangement shown, when the hand-lever D' isin' its uppermost position,

the gear-unit d wi'll'he shifted tothe left as seeny by Figs? and 12, with the efiect that gear. 2Z fwill1nesh with gearlDF, This I is tlie-p ositionindicated by d D on Fig;

ill).- So also, when the hand-lever D is "in; e a

that also meshes withat'he rack-teeth '82 of a reciprocating shift-rod 83 which :carries its lowermost position (d? D theflgeard will 'niesh withthegear'D Thus the vertical movement of the h'anddever D will determine the position of the gear-unit -D 5; The construction is such, imoreoven that the horizontal movements of the hand-lever D Iwilldalsojeontrol .the position ofthe gearli'nit Df. Av pin 59 pivots the hand 'le'ver to" a radialfexte'nsioh 600i the sleeve and a."

ied-(31 extends eoaXially through thelhore of-the, sleeve'55-andit provides a rack 62 meshing with the teeth of the gear-segment ."52 so; that; horizontal oscillations of the hand -lever D"wil'lhreciprocate' the .rod "61 ande by nieans of"another rack 63, this re oiproeating'n1otion is 11tiliZed to 'osilla'te a -lever 64wh'ich is pivoted at 6 5 and hasanarm 66'. terminating -i n agearsegment mesh-1 ing withitherack .63.--*;Thi. VQ 64 ls terminatesfjin a' fshoe 6T ridin inia circular: groove 68 of the g'ear-unitd seas-to con t rol the positions thereof; Hence, when the hand-lever -D.' -i's fswimg to" the right -to' the DO itiOIi dD indicated hyS-Fig. 10, tlfi'e gear Y (Z? will he broiightinto In esh with the. gear VHF and; eonve'rsely;whenit' is swung to the let'-t' into thepositio'n 037D. the: gearat will '.n'1 eShI--with. thefgear; D7 [The relation of; these w arioijrs geared; d-,- 'd and d to the 1, transmission" system; is such. 1 that V but one of} "them 111a}? --be operating at the same time;

otherwise sonjiething would. have to break and eire -im staneefis" precluded 'by ithe rise of'the "X slot the -plate 151.1 In order" that the-hand-l'ever" .D remain in any one of its' various]positions;*hall'pawls' 69 and-T0 fwill ipreferably ,he 'provided to to: operate with -.app rQP1i7iaterecesses in; the

lever 64 the sleeve 55 respectively, as will he understood by referring to Fig. 12.

The other. hand-lever G determines the setting or relation of theback-gears of'thev dt'eedeehange mechanism'and it has va shank 'passing through' the square opening'in the,

gUard pIate-SI. and also has a flattened endportion 71 entering a-radial-slot 72in the exposed end-portion ofa-sleeve '74 which is also jo ii-naledin the gear-box C}. This hand-lever is pivoted to the sleevev by means of a tangential pin'ZhsQ-that the sleeve may be-r'otated when the ,han'deIeX- er .G is lifted also providesa 'crank arm 76 terminating in a'shoe 7.7 rid-ingin a slot 78 of'the' gear-' unit 9. WVhenfthe'hand-lever is lifted to 1 the upper .edge'ofthe square-opening inthe plate 51' v as'indioated .by'D g ,.then will the gear'Dt" transmitmotion t0 the gear 9 and eonVersely,-.when .the hand-lever G is depressed, asindicated by D Gr on Fig. 10,-

the'n'will the gear, D transmit motion to the gear g The hand lever G termlnates 1n :1 gear-segment 7 9 meshing with areciprocating-rack"80 which in turn meshes with. an lip-standing elongated pinion 81 an arm or'fork' 84;- eoo'pera'ting' With the or depressed. The other end of this sleeve will m'ove as a unit 'and,when it is thrown to the-other side, the-geanGfwill transmit motionto the gearh. It is to he'observed that inasmuch as it"is'in eonsequentia1 from the standpoint of'injury whether any of the last-mentioned gears are infoperation' simultaneously, it is possible and even more con- .vement to employ-a square opening instead.

of the.n ore' restricted. f(' 1'n1 ,-since' the at- {tendant 'can throw off the-lever G without anxiety as to theeonsequences' and Withgreater facility.

From the foregoin itwill he observed that the hand-levert may he moved from on position'to another successively through lthetwo reetilinear coordinates defining the point of, location space, or it may be moved, diagonally from the endpoint to the 1 other; it-having acompou'nd movement in the latter instance." In all cases, --howe"ver, the movement ot the hand-lever Whether compound 'or simple will be resolved into its components ,byithei meehanismjv connecting it '=-"\vithfl the tWojshifting-clutches so that the -movements of [the one -clutch will correspond withzthefone eoord inate-ofmovement of the .hand-lever, and theo the'r; eluteh will correspondwith the other e'jotirdinate. By means of 'this-;=hand -leverqU and. the. two hand-- levers 1D and G, a complete control is ez zercised over. 'the'table.,-

; .The'ee eh ngememanism Mei mu h simplified by avoiding the use of tumbler arrangements and by effecting all feed changes intermeshing gears laterally.

Having thus revealed this invention, we claim as new and desire to secure the following combination of elements, by Letters Patent of the United States l. A mechanism of the nature disclosed V combining a power-driven member; a propelled element; a first transmitting means adapted operatively to connect said member with said element and constructed to transmit motion positively at a low rate of travel, said means comprising a Weak part adapted to break under undue strains and mounted to be readily replaced; a second transmitting means interchangeably available with said. first transmitting means to cause said element to be propelled at a high rate of travel, said second transmitting means comprising impositive means affording a momentary lag in attaining a materially different rate of propulsion of said element under abrupt changes in the mechanical connections.

2. An automatic milling-machine organization combining a reciprocatory worksupporting table; a' rotary cutter-support;

table-propelling mechanism comprising two N clutch-members; automatic trip-means for determining the positions of said clutchmembers; a series of dogs movable with said table, the dog next to the end-dog of said series being adapted to actuate said trip means to cause it to shift one of said clutchmembers to feed said table in a given direction, and the end-dog of said series being adapted then to actuate said trip-means to shift the other of said clutch-members into a position rendering said mechanism inoperative to propel said table; and means automatically coiiperating to maintain said last-mentioned clutch-member in its inoperative position when said first-mentioned clutch-member is in a table-feed position.

3. An automatic trip instrumentality of the nature disclosed combining a movable member; a plurality of dogs secured at predetermined stations to said member; tripmeans normally positioned to be actuated by each of said dogs" in succession during an advance movement of said member; a mechf anism for propelling said member at a rate determined by said trip-means and means for enabling said trip-means to be shifted to a position beyond the influence of said dogs during a return movement of said member.

4. A mechanism of the nature disclosed comprising a power-driven member and a member ultimately deriving motion therefrom; a first means for transmitting motion therebetween; a second means for determining the rate at which said first means will cause said table to travel; a motionreverser 01 determini g the direction of travel of said table; and a single control for; motion-reversing means in serial rela- 1 tion with said propelling-means; means determining the rate of propulsion of said propelling-means; a member mounted adjacent said table and adapted to control both said motion-reversing means and also said rate-determining means; and a table-actuated dog adapted to shift said member to enable it to operate one of said means.

6. A trip instrumentality of the nature disclosed combining a table, a propelling mechanism therefor comprising a first shift device adapted to enable said mechanism to effect either 'a feed or a quick-traverse of said table and also comprising a second shift-device adapted either to stop said table or to determine the direction of travel there.- of; trip-means for controlling said shiftdevices; a first dog carried by said table and will actuate said first. shift-device in one direction; another dog carried by said table and adapted so to move said trip-means as to cause said first shift-device to be moved in the opposite direction; and another dog on a:

said table adapted so to move said tripmeans as to actuate said second shift-device.

7 A trip mechanism of the nature disclosed combining a table providing an upper and a lower series of dogs; a trip-member providing two impact-surfaces at different elevations and extending in different angular relations with respect to the axis of said trip-member; means other than said abovespecified dogs for turning said trip-member about its axis to bring the one or the other contact-surface into operative relation with the one or the other series of dogs; and mechanism for propelling the table in accordance with the position of said tripmember determined by said dogs.

means.

f A trip mechanism of-the nature -d1sclosed combining a reciprocating table; a

' means, or the other cam and the detenttrip member; and means for moving said i a trip-member mounted to have a movement of rotation and also of translation; detentmeans resiliently resisting one of said movements of said trip-member; a dog movable in accordance with said table adapted positively to impart the other movement to said trip-member against the resistance of said detent means.

10. A trip instrumentality of the nature revealed combining a movable member; a plurality of dogs rigid with said member and located at predetermined intervals thereon; a trip-means adapted in one posi tion to be actuated successively by an advance of said dogs; mechanism for pro-' pelling said member at a rate determined by said trip-means; and means for automatically shifting the position of said tripmeans to render it non-responsive to an actuation by said dogs during a return movement thereof.

11. A machine-tool organization combining a spindle; a table; a prime-mover; a-

speed-change mechanism between the spindle and the prime-mover; a first transmissionconnecting said spindle and said prime- .mover through said speed-change mechanism; a feed-change mechanism adjacent the table and remote from the prime-mover;

a motion-reverser"between the feed-change mechanism and said table; a second transmission adapted to connect said primemover, said feed-change mechanism, said motion-reverser. and said table together in series in the order recited; a hand-operated member located adjacent the table; and

shifting means actuated by vertical movements of said member to render operative or inoperative said feed-change mechanism,

and actuated by horizontal movements of said member to determine the efiectof said motion-reverser, whereby the feed of said table will be denoted by the vertical position of said hand-operated member'and whereby its direction of travel will be indicated by the horizontal direction in which said member points.

12. A machine-tool of the nature disclosed combining'a stationary frame-unit; a bodilymovable frame-unit; a table slidable on said bodily-movable frame-unit; a non-translating feed-screw journaled on said bodilymovable frame-unit and cooperating with a nut reciprocating with said table; a feedchange mechanism carried by'said movable frame-unit near one side of said stationary frame-unit and underneath said table; operating instrumentalities extending from said feed-change mechanism and located at the front side of the longitudinal edge of said table; and automatic trip-means adjustably mounted at the longitudinal edge of given direction to said table, and the enddog of said series being thereby enabled to actuate said trip-means during the quicktra-verse to shift the other of said clutchmembers into a position causing said mechanism to propel said table in the opposite direction without changing its rate of quicktraverse.

ll. A trip-instrumentality of the nature disclosed combining a reciprocating table; a

and having an extension terminating adjacent the longitudinal edge of said table; a dog also on said table adapted to swing said part about its vertical axis; a vertically movable part; another dog on said table adapted vertically to move said part; a table -.propelling mechanism; and means governed by said trip-member for determining the operative effect on said propelling mechanism.

15. A trip-instrumentality combining a clutch-member adapted to assume different 'positionsg'a detent-means adapted to maintain said clutch-member in any one of said positions; means adapted to deprive said detent means of the capacity of maintaining said clutch-mechanism inone of said posi tions; and a propelling means'controlled by said clutch-member.

16. A machine-tool organiaation combining a stationary frame-unit; a tool-supporting member mounted from the upperend thereof; a table; a bodily-movable frameunit intervening between the table and the stationary frame-unit and providing for relative movements between said frame-unit and said table in two. horizontal transverse directions; a feed-change mechanism arranged on said bodily-movable frame-unit; table-propellingmeans adapted to 'efi ect a relative feed between said table and said tool-supporting memb er in one of said ditraverse rate or at the rate of feed detertrip-member .pivoted about a vertical axis mined by said feed-change mechanism; a

manually operable element arranged at the -Front of the machine-tool and constituting means for controlling said feed-change mechanism, whereby the rate of relative iced between the tool-supporting member and said table may be varied, and another element operable independently-of said manually-operable element for causing said table-propelling means to execute a quicktraverse of said table.

17. A machine-tool of the nature disclosed combining a reciprocating member; a supporting-member therefor; a plurality. of dogs secured at intervals to one of said members; trip-means mounted on the other member and adapted by the relative movement of said members to be impacted successivelyby a number of said dogs; means for propelling one of said members in the manner determined by said trip-means; and

'means for automatically shifting said tripmotion-reverser, and said table together in series in the order recited; a hand-operated member located adjacent the table and mounted to swing'either horizontally or vertically; and shifting means actuated by said member when moved vertically to a predetermined position for causing the table to 'Feed-at'thc rate determined by said feedchange mechanism and in the direction indicated by the horizontal direction of said hand-operated member and determined by said i'notion-reverser.

19. A machine-tool organization combining a prime-mover; a table; a frame-unit;

uprising-across the plane of the table; a tool-supporting member located above the table and having its weight carried by said frame-unit; a feed-change mechanism; transmitting means adapted to connect said prime-mover with said table either inclusive or exclusive of said feed-change mechanism; a. hand-lever located adjacent the longitudinal edge of the table remote from the said frame-unit; and means enabling said handlever to determine the operative efi'ect of saidtransmittingLmeans either by including or byexcluding said feed-change mechanism.

20. An automatic milling machine organization combining a reciprocatory work-supporting table; a rotary cutter support; table-propelling mechanism comprising two clutclrmembers'; automatic trip-means for determining the positions of said clutchmembers; means embodying a lost-motion detent connecting said trip-means with one of said clutch-members; a series of dogs movable with said table, the dog next to the end-dog of said series being adapted to actuate said trip-means to cause it through said lost-motion connecting means to shift impositively one of said clutch-members to cause said table to feed in a given direction; means establishing a positive connection between said trip-means and the other clutchmember when said first 'mentioned clutchmember occupies its last-mentioned position; the end dog of said series being thereby adapted positively to actuate said tripmeans to shift positively the other of said clutch-members into a position rendering said mechanism inoperative to propel said table; and means automatically cooperating to maintain said last-mentioned clutch-memher in said inoperative position.

21. An automatic trip instrumentality of v the nature disclosed combining a reciprocating table; a first and a second shiftable tripelement arranged in closely-nested relation adjacent the longitudinal edge of said table; a first and a second dog mounted at the longitudinal. edge of said table and each adapted to actuate the respective trip-element; mechanism for propelling said table; a first and a second clutch determining the operative effect of said propelling-mechanism; and connections between said'clutches and said parts whereby the position of the one clutch will be in accordance with. the position of the one part, and the position of, the other clutch'will be in accordance with the position of the other part.

22. A machine-toolorganization combining a work-supporting member; a tool-supporting member; a pair of gears; a part adapted to be progressively moved to shift said pair of gears to enable them to yield two speeds; a gear in serialtransmitting relation with said pair; a device for shifting said gear to enable the same to be driven either from its teeth or from its side to yield two different speeds; and a hand-operated element connected both with said part and with said device whereby when moved in one way it will operate said device without operating said part, and when moved in an-' other Way it will operate said partwithout operating said device; and transmission means operatively connecting said series of actuated successively by dogs in thetiirstmentioned path'of'traivel; amechanism for propelling said table in the manner deternism to effect a quick-traverse of said table or inclusive thereof to feed said'table; two hand-levers located adjacent the longitudinal edge'of the table remote from the said stationary frame-unit; and means enabling the one hand-lever to determine the operative eiiect of said teed-change mechanism and enabling the other hand-lever to etlect a connection or a maintained disconnection between said transmitting means and said feed-change mechanism.

An automatic milling-machine organization combining a reeiprocatory work-supporting table; table-propelling mechanism comprising two clutch-members; automatic trip-means for determining the positions of said clutchmembers; a series of dogs movable with said table, the dog next to the end-dog of said series being adapted to actuate said trip means to cause it to shift one of said clutchmembers to cause said table to feed in a given direction, and the end-dog of said series being thereupon adapted to actuate said trip-means to shift the other of said clutch-members into a position rendering said mechanism inoperative to propel said table; and means automatically coiiperati-ng to maintain said last-mentioned member in its. inoperative position.

26. A machine-tool organization combining a tool-supporting member and a worksupporting member; a prime-mover; a feedchange mechanism; a shear-pin; an adjustable impositive meansifor transmitting motion frictionally; and a transmitting means adapted to establish an operative propelling relation between said prime mover and one oi said members serially through both said sheaf-pin and said feed-change mechanism to propel said member at a feeding rate, said means being interchangeably available to establish a propelling relation at 'a quicktraverse rate between said prime-mover and said member through said impositive means, exclusive of said feed-change mechanism.

27. A trip-mechanism of the nature disclosed combining a reciprocating table; a first-series of dogs adjustable thereon in one a rotary cutter-support;

clutchv path of travel; the second-series of dogs arranged in a second path of travel and adjustable independently of the positions oocupied by the vmembers of the first-series; a trip-means adapted in one position to be ac tuated in succession by the dogs of the first series and in another position to be actuated in succession by the dogs of the second-series; a mechanism for propelling a table at rates determined by said tripm'eans; a dog adjacent one end of said table adapted to actuate said trip-means to reverse the direction of travel of said table; and 'a dog at the other end of said table adapted also to reverse the direction of travel thereof.

28. A detent-mechanism of the naturedisclosed combining a rotatable-member provided with two difi'erently configurated cam-surfaces; detent means adapted to cooperate with the one or the other of-said cam surfaces; a mechanism having" its operative effect determined by the angular position of said member; and meansefor efiectinga relative displacement between said detent means and said cam-surfaces, whereby said detent means may be brought into cooperative relation with either one or the other of said cam-surfaces.

29. A machine-tool organization combining a work-supporting member; a -tool-supporting member; a first gear; a part adapted to be progressively moved to shift said gear to enable it to yield a series of speeds; a second gear in serial relation with said first gear; a device for shifting said second gear to enable the same to yield difi'erent speeds, and a hand-operated element connected both with said part and with said device whereby when moved in one way it will operate said device without operating said part, and when moved in another way it will operate said part without operating said device, and when moved in still another way it will simultaneously operate both said part and device; and transmission means operatively connecting said gears n serial propelling relation with one of said members.

30. A machine -tool of the nature disclosed combining a work-supporting mem her and a tool-supporting member; a plurality of dogs mounted at spaced intervals on one of said members; trip-means stationed adjacent the path of travel of said dogs and adapted to be shifted into position to be actuated successively by said dogs; and'a'dogalso secured to said member and adapted at a predetermined station to shift the position of said trip-means to render it non-responsive to said dogs during a returnpassage thereof.

31. A machine-tool organization combining a tool-supporting" member and a worksupporting member; a prime-mover; a first train comprising transmitting elements arranged in serial relation with both a feedchange mechanism and a shear-pin; means for causing one of said members to feed at a '5 slow rate by motion derived from said prime-mover through said train; and a quick-traverse transmission adapted to be said element to be unaffected by a vertical swing thereof but operated thereby when said element is swung horizontally; and transmission means operativelyr connecting said feed-change mechanism in propelling relation with one of said members.

33. A.'trip-instrumentality of the nature parallel slots at its longitudinal edge; a first-series of dogs adjustably secured in said first slot and comprising a dog formed in one Way and another dog formed in an other way; a second-series of dogs secured in said second slot; trip-means adapted to be positioned to be actuated 'by one or the other series of dogs; and means for shifting said trip-means.

84. trip-instrumentality of the nature disclosed combining two shiftable clutchmembers; an element connected with each of said clutch-members and adapted when moved in one manner to actuate the one int5 dependently of the other; detent-mechanism for resiliently maintaining said element in its different positions when moved as above stated; said element being movable in a different way to actuate the other clutch-element; and detent-means for maintaining said element in its various positions when moved as last stated. c

35. A machine-tool organization combining a work-supporting member; a tool-supporting member; a guide-member providing an X-slot; mechanism for actuating one of said members; a. hand-operated element pivotally supported at one end and extending forwardly through said X-slot and terminating in a hand-grasp whereby it'may be oscillated either vertically or horizontally; means operatively. connecting said element With said mechanism whereby a vertical swing of said element will estab- 5 lish one operative relation between said disclosed combining atable providing two mechanism and the element actuated thereby, and whereby a horizontal swing of said element will establish another operative relation between said mechanism and .one of said elements; and transmission means enabling said mechanism to propel one of said members.

36. A machine-tool of the nature disclosedcombining a frame-unit; a casing secured to the front side thereof; a powerdriven shaft extending through the rear wall of said casing and terminating in a journal mounted on the front wall thereof;

a table slidable transversely on the frameunit; a feed-screw journaled on said frameunit and cooperating with a nut reciprocating with said table; a feed-change mechanism in said casing establishing operative connection therebctwcen; and hand-operating instrumentality journaled at the outer side of the front wall of said casing and located forward, of the longitudinal front edge of said table, a

37. A trip-mechanism of the nature revealed combining a reciprocating table; a table-support; a first part pivotally mounted on said table-support to oscillate about a vertical axis and having a portion extending toward said table; a second-part movablv mounted on said table-support in underlying relation with said first-part; a dog movable with the table to swing said first part; another dog movable with the table to actuate said second part; propellingmechanism for the table; and means governed by said parts for determining the operative effect of said propelling-mecha-- device whereby when swung vertically it will operate said device without'operating said part, and when swung horizontally it will operate said part without operating said. device; and transmission means operativelyconnecting said series of gears in serial propelling relation with one of said members.

39. A milling machine combining a table;

a prime-mover; a first train comprising in serial relation a frictionclutch and quicktraverse transmitting means; a second train comprising in serial relation a shear-pin and means for transmitting motion at a slow rate corresponding to a table feed; and 

